Differentiable graph-structured models for inverse design of lattice materials

IF 7.9 2区综合性期刊 Q1 CHEMISTRY, MULTIDISCIPLINARY

Cell Reports Physical Science Pub Date : 2023-10-01 DOI:10.1016/j.xcrp.2023.101586

Dominik Dold, Derek Aranguren van Egmond

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引用次数: 3

Abstract

Architected materials possessing physico-chemical properties adaptable to disparate environmental conditions embody a disruptive new domain of materials science. Fueled by advances in digital design and fabrication, materials shaped into lattice topologies enable a degree of property customization not afforded to bulk materials. A promising venue for inspiration toward their design is in the irregular micro-architectures of nature. However, the immense design variability unlocked by such irregularity is challenging to probe analytically. Here, we propose a new computational approach using graph-based representation for regular and irregular lattice materials. Our method uses differentiable message passing algorithms to calculate mechanical properties, allowing automatic differentiation with surrogate derivatives to adjust geometric structure and local attributes of individual lattice elements to achieve inversely designed materials with desired properties. We further introduce a graph neural network surrogate model for structural analysis at scale. The methodology is generalizable to any system representable as heterogeneous graphs.

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晶格材料反设计的可微图结构模型

建筑材料具有适应不同环境条件的物理化学特性，体现了材料科学的一个颠覆性新领域。在数字设计和制造技术进步的推动下，形成晶格拓扑结构的材料能够实现一定程度的属性定制，这是散装材料所无法提供的。他们的设计灵感来自于自然界不规则的微建筑。然而，这种不规则性释放的巨大设计可变性对分析探索具有挑战性。在这里，我们提出了一种新的计算方法，使用基于图形的表示规则和不规则晶格材料。我们的方法使用可微信息传递算法来计算力学性能，允许与替代导数的自动微分来调整单个晶格元素的几何结构和局部属性，以获得具有所需性能的逆向设计材料。我们进一步引入了一种用于结构分析的图神经网络代理模型。该方法可推广到任何可表示为异构图的系统。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Cell Reports Physical Science Energy-Energy (all)

CiteScore

11.40

自引率

2.20%

发文量

388

审稿时长

62 days

期刊介绍： Cell Reports Physical Science, a premium open-access journal from Cell Press, features high-quality, cutting-edge research spanning the physical sciences. It serves as an open forum fostering collaboration among physical scientists while championing open science principles. Published works must signify significant advancements in fundamental insight or technological applications within fields such as chemistry, physics, materials science, energy science, engineering, and related interdisciplinary studies. In addition to longer articles, the journal considers impactful short-form reports and short reviews covering recent literature in emerging fields. Continually adapting to the evolving open science landscape, the journal reviews its policies to align with community consensus and best practices.